BMC Cell Biology (Sep 2008)

Establishment and characterization of immortalized Gli-null mouse embryonic fibroblast cell lines

  • Gipp Jerry J,
  • Bijlsma Maarten F,
  • Lipinski Robert J,
  • Podhaizer David J,
  • Bushman Wade

DOI
https://doi.org/10.1186/1471-2121-9-49
Journal volume & issue
Vol. 9, no. 1
p. 49

Abstract

Read online

Abstract Background Hedgehog (Hh) signaling is a conserved morphogenetic pathway which plays critical roles in embryonic development, with emerging evidence also supporting a role in healing and repair processes and tumorigenesis. The Gli family of transcription factors (Gli1, 2 and 3) mediate the Hedgehog morphogenetic signal by regulating the expression of downstream target genes. We previously characterized the individual and cooperative roles of the Gli proteins in Hh target gene regulation using a battery of primary embryonic fibroblasts from Gli null mice. Results Here, we describe the establishment of spontaneously immortalized mouse embryonic fibroblast (iMEF) cell lines lacking single and multiple Gli genes. These non-clonal cell lines recapitulate the unique ligand mediated transcriptional response of primary MEFs. While loss of Gli1 had no effect on target gene induction, Gli2 null cells demonstrated reduced target gene induction while Gli3 null cells exhibited elevated basal and ligand-induced expression. Target gene response in Gli1-/-2-/- iMEFs was severely reduced while Gli2-/-3-/- iMEFs were incapable of ligand-induced transcriptional response. However, we found that both Gli1-/-2-/- and Gli2-/-3-/- iMEFs exhibited robust leukotriene synthesis-dependent migration responses to Hh ligand, demonstrating that this response is not transcriptionally-dependent. Conclusion This study provides fundamental characterizations of the transcriptional and non-transcriptional Hh responsiveness of a battery of Gli-null iMEFs. Moving forward, these cell lines should prove a valuable tool set to study the unique functional regulation of the Gli proteins in a Hh-responsive cell-type.